Pilot Operating Handbook - Just Aircraft NZ · PDF file3 Record of Revisions Pilot Operating Handbook No. POH001 Any Revisions of the present manual, except actual weighing data, must
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PILOT OPERATING HANDBOOK No. POH001 REVISION NC 1/10/2014
MANUFACTURER:
JUST AIRCRAFT CO. MODEL: SUPERSTOL AIRPLANE REGISTRATION NUMBER ____________ AIRPLANE SERIAL NUMBER _____________ DATE OF ASSIGNMENT _____________
APPROVED TROY WOODLAND //S/ 1/10/2014
_______________________
Just Aircraft Co. 170 Duck Pond Rd
Walhalla, SC SC 29691 (864) 718-0320
www.justaircraft.com
2
MANDATORY SERVICE ALERTS
As the Service History of the airframe evolves, Just Aircraft will from time to time issue mandatory Service Alerts, which will detail any changes to the aircraft operation instructions, maintenance manuals or any other details that Just Aircraft deems necessary for which the owners to be notified. The web address for Service Alerts is www.justaircraft.com It is the responsibility of the operator to keep up to date with any engine related service alerts and any Rotax Directives through the Rotax website.
The web address for Rotax Service Bulletins is http://www.rotax.com
WARNING
The information in this manual needs to be followed, and it is not acceptable to make changes to the materials and or physical features of this aircraft. In particular, the grades of bolts that have been utilized in the manufacture of this aircraft are critical for its continuing airworthiness. Never replace bolts with any other size or grade. Grade 8 bolts are not interchangeable with aircraft (AN) Grade Bolts. The fatigue characteristics of aircraft grade bolts are superior to other bolts and allow longer safe service life under cyclic loads like those experienced in aircraft. The length of bolt is important. If a shorter bolt is used the threads may encroach on the load bearing area which increases the stresses experienced by it.
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Record of Revisions Pilot Operating Handbook No. POH001
Any Revisions of the present manual, except actual weighing data, must be
recorded in the following table according to information from the Manufacturer.
New or amended text in the revised pages will be indicated by a black vertical line
on the left had side of the page.
Revision
Number
Affected
Section
Affected
Pages
Date Approval Date Date Inserted Signature
Rev A -
ASTM
update
all all 1/10/2014 TW//s/ 1/10/2014 1/10/2014 TW//s/
4
6.3 Table of Contents
Title Page,
Record of Manual Revisions Page,
Table of Contents Page,
Introduction,
6.4 Introduction—Definitions
6.5 No. 1 – General Information:
6.5.1 Introduction to airplane.
6.5.1.1 Placards and Markings
6.5.2 Summary of the performance specifications to include:
6.5.2.1 Gross Weight,
6.5.2.2 Top speed at sea level and cruise speed at a stated
power setting and altitude,
6.5.2.3 Full fuel range
6.5.2.4 Rate of climb (Vx to Vy),
6.5.2.5 Stall speed: Flaps not extended and flaps extended,
6.5.2.6 Total fuel capacity, total usable fuel, and approved
types of fuel, and
6.5.2.7 Maximum engine power output at a stated RPM.
6.5.3 Warning notices
6.6 No. 2 – Limitations:
6.6.1 Airspeed Indicator speed range markings.
6.6.2 Stalling speeds at maximum takeoff weight (VS and
VS0),
6.6.3 Flap extended speed range (VS0 to VFE),
6.6.4 Maneuvering speed (VA) at gross weight and minimum
weight,
6.6.5 Never exceed speed (VNE),
6.6.6 Service ceiling,
6.6.7 Load factors,
6.6.8 Approved maneuvers,
6.6.9 Total fuel capacity, total usable fuel, and approved
types of fuel,
6.6.10 Maximum engine power output at a stated RPM,
6.6.11 Applicable environmental limitations, if any, and
6.6.12 Applicable VFR night or IFR use limitations, if any.
6.7 No. 3 – Emergency Procedures:
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6.7.1 General Information,
6.7.2 Airspeeds for Emergency Procedures, and
6.7.3 Emergency Checklist. Provide these as applicable to
the LSA covered in the POH:
6.7.3.1 Engine fire during start,
6.7.3.2 Engine failure during takeoff,
6.7.3.3 Loss of engine power in flight,
6.7.3.4 Emergency landing without engine power,
6.7.3.5 Precautionary landing with engine power,
6.7.3.6 Fire in flight,
6.7.3.7 Loss of oil pressure,
6.7.3.8 High oil pressure,
6.7.3.9 Emergency descent,
6.7.3.10 Alternator failure,
6.7.3.11 Overvoltage,
6.7.3.12 Inadvertent spin,
6.7.3.13 Inadvertent icing encounter,
6.7.3.14 Loss of primary instruments, and
6.7.3.15 Loss of flight controls.
6.8 No. 4 – Normal Procedures:
6.8.1 Preflight check,
6.8.2 Engine starting,
6.8.3 Taxiing,
6.8.4 Normal takeoff,
6.8.5 Best angle of climb speed (VX),
6.8.6 Best rate of climb speed (VY),
6.8.7 Cruise,
6.8.8 Approach,
6.8.9 Normal landing,
6.8.10 Short field takeoff and landing procedures,
6.8.11 Soft field takeoff and landing procedures.
6.8.12 Balked landing procedures,
6.8.13 Any other useful pilot information.
6
6.9 No. 5 – Performance:
6.9.1 Takeoff total distance over a fixed-height obstacle
using normal takeoff procedures as defined in 6.8.4,
6.9.2 Landing total distance over a fixed-height obstacle
using normal landing procedures as defined in 6.8.9,
6.9.3 Rate of climb,
6.9.4 Cruise speeds, and
6.9.5 RPM setting and fuel consumption.
6.10 No. 6 – Weight and Balance and Equipment List:
6.10.1 Weight and Balance Chart,
6.10.2 Operating weights and loading (occupants, baggage,
fuel, ballast)
6.10.3 Center of gravity (CG) range and determination, and
6.10.4 Installed optional equipment list affecting weight and
balance or a reference as to where this information can be
found.
6.11 No. 7 – Description of Airplane and Systems:
6.11.1 General,
6.11.2 Airframe,
6.11.3 Flight controls,
6.11.4 Instrument panel,
6.11.5 Flight instruments,
6.11.6 Engine, and
6.11.7 Propeller.
6.12 No. 8 – Handling and Servicing:
6.12.1 Introduction,
6.12.2 Ground handling,
6.12.3 Towing instructions,
6.12.4 Tie-down instructions,
6.12.5 Servicing fuel, oil, coolant, and other operating fluids
as applicable,
6.12.5.1 Approved fuel grades and specifications,
6.12.5.2 Approved oil grades and specifications,
6.12.6 Cleaning and Care.
7
6.13 No. 9 – Supplements:
6.13.1 Any additional information the manufacturer wishes
to add regarding the airplane.
6.13.2 Operation of optional equipment or accessories.
6.13.3 Flight training supplement (FTS).
6.13.4 Information the owner can use for:
6.13.4.1 Improvements or Corrections,
6.13.4.2 Continued Operational Safety Reporting, and
6.13.4.3 Change of Address Notice.
8
6.4 Introduction—
6.4.1 The list of the ASTM standards that currently apply:
F2245 Standard Specification for Design and Performance of a Light Sport
Airplane
F2279 Standard Practice for Quality Assurance in the Manufacture of Fixed Wing
Light Sport Aircraft
F2483 Standard Practice for Maintenance and the Development of Maintenance
Manuals for Light Sport Aircraft
F2295 Standard Practice for Continued Operational Safety Monitoring of a Light
Sport Aircraft
F2339 Standard Practice for Design and Manufacture of Reciprocating Spark
Ignition Engines for Light Sport Aircraft
F2745 Standard Specification for Required Product Information to be Provided
with an Airplane1
F2746 Standard Specification for Pilot’s Operating Handbook (POH) for Light
Sport Airplane
F2316 Standard Specification for Airframe Emergency Parachutes
F2506 Standard Specification for Design and Testing of Light Sport Aircraft
Propellers1
9
6.4.2 The name and contact information of the manufacturer of the aircraft.
manufacturer:
Just Aircraft Co.
170 Duck Pond Rd
Walhalla, SC 29691
(864) 718-0320
Web: www.justaircraft.com
Model: Superstol
Web: www.justaircraft.com
6.4.3 Data Location and Contact information for recovery
of certification documentation, should the original manufacturer
lose its ability to support the make and model:
Troy Woodland
170 Duck Pond Rd
Walhalla, SC 29691
(864) 718-0320
6.4.4 Definitions SYMBOLS, ABBREVEATIONS AND TERMINOLOGY
The following definitions are of symbols, abbreviations and terminology used throughout the hand book
and those which may be of added operational significance to the pilot. General Airspeed Terminology and
Symbols
BHP- Brake horsepower ( = rated horsepower of the engine).
CAS- Calibrated airspeed means the indicated speed of an aircraft, corrected for
position and instrument error. Calibrated airspeed is equal to true airspeed in
standard atmosphere at sea level.
10
GPH- Fuel consumption in gallons (U.S.) per hour
KCAS- Calibrated airspeed expressed in “Knots”.
C.G.- Center of Gravity.
IAS- Indicated airspeed is the speed of an aircraft as shown on the airspeed indicator.
KIAS- Indicated airspeed expressed in “Knots”
L- Left
R- Right
RPM- Revolutions per minute.
S.L.- Sea level
TAS- True airspeed is the airspeed of an airplane relative to undisturbed air which is
the CAS corrected for altitude and temperature.
V- Speed
VA- Maneuvering speed is the maximum speed at which application of full available
aerodynamic control will not overstress the airplane.
VFE- Maximum flap extended speed is the highest speed permissible with wing flaps
partially or fully extended.
VNE- Never exceed speed is the limit that may not be exceeded at any time.
VC- Maximum structural cruising speed is the speed that should not be exceeded
except in smooth air and only with caution.
VS- Stalling speed or the minimum steady flight speed at which the airplane is
controllable (flaps up).
VSO- Stalling speed at which the airplane is controllable in the landing configuration.
VX- Best angle-of-climb speed is the air speed which delivers the greatest gain of
altitude in the shortest horizontal distance.
VY- Best rate-of-climb speed is the air speed which delivers the greatest gain in
altitude in the shortest time.
Meteorological Terminology
ISA- International standard atmosphere in which the air is a dry perfect gas, the
temperature is at sea level is 15o Celsius (59
o Fahrenheit), the pressure at sea
level is 29.92 inches hg. (1013 mb), and the temperature gradient from sea level
up is: -1.98o C per 1000 ft or -6.5
o C per 1000 meter, or -3.57
o F per 1000 ft.
OAT- Outside air temperature is the free air static temperature, obtained either from
in-flight temperature indications or ground meteorological sources, adjusted for
instrument error.
Indicated Pressure Altitude- The number actually read from an altimeter when the
barometric subscale has been set to 29.92 inches of mercury (1013 millibars).
Pressure Altitude- Altitude measured from standard sea level pressure (29.92 inches
Hg) by a pressure or barometric altimeter. It is the indicated pressure altitude
corrected for position and instrument error. In this POH, altimeter instrument
errors are assumed to be zero.
Station Pressure- Actual atmospheric pressure at field elevation.
Wind- The wind velocities recorded on the charts of this POH are to be understood as the
headwind or tail wind components of the reported winds.
11
Units
Speed- Kts (Knots) = 1.15 mph (miles per hour)
Pressure- PSI = pounds per square inch, in Hg = inches of Mercury,
in mb = millibar.
Distances- in. = inches = 25.4 millimeters, ft = foot (feet) = .305 meters
Weights- Kg = kilograms = 2.2 lbs (pounds)
Power Terminology
Takeoff Power- Maximum power permissible for takeoff.
Maximum Continuous Power- Maximum power permissible continuously during
flight.
Maximum Climb Power- Maximum power permissible during climb.
Maximum Cruise Power- Maximum power permissible during cruise.
Engine Instruments
CHT Gauge- Cylinder head temperature
Airplane Performance and Flight Planning Terminology
Climb Gradient- The demonstrated ratio of the change in height during a portion of a
climb, to a horizontal distance traversed in the same time interval.
Demonstrated Crosswind Velocity- The velocity of the 90o crosswind component for
which adequate control of the airplane during takeoff and landing was actually
demonstrated.
Weight and Balance Terminology
Reference Datum- An imaginary vertical plane from which all horizontal distances are
measured for balance purposes: the nose.
Station- A location along the airplane fuselage centerline given in terms of distance from the
reference datum.
Position or Arm- The horizontal distance from the reference datum to the center of gravity
(C.G.) of an item parallel to fuselage centerline.
Moment- The product of the weight of an item multiplied by its arm. (Moment divided by a
constant is used to simplify balance calculations by reducing the number of digits.
12
Center of Gravity (C.G.)- The point at which an airplane would balance if suspended. Its
distance from the reference datum is found by dividing the total moment by the total weight of
the airplane.
C.G. Arm- The arm obtained by adding the airplane’s individual moments and dividing the sum
by the total weight.
C.G. Limits- The extreme center of gravity locations within which the airplane must be
operated at a given weight.
Usable Fuel- Fuel available for flight planning.
Unusable Fuel- Fuel remaining after a runout test has been completed in accordance with the
design standards.
Standard Empty Weight- Weight of a standard airplane including unusable fuel, full operating
fluids and full oil.
Empty Weight- Standard empty weight plus optional equipment.
Payload- Weight of occupants, fuel and baggage.
Useful Load- Difference between takeoff weight, and empty weight.
Maximum Takeoff Weight- Maximum approved weight.
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6.5 No. 1 General Information
6.5.1 Introduction to airplane The airplane Pilot Operating Handbook has been prepared to provide the pilots and instructors
with information for the safe and efficient operation of this airplane.
Airplane and Systems Description
The Superstol is a two seat light airplane for primary training. It is a high wing, strut braced
monoplane of “classic” aerodynamic layout with closed cockpit, non-retractable landing gear,
with steerable nose wheel. It is equipped with a Rotax 912 engine (or other approved engines)
and a three blade, ground adjustable pitch propeller.
Performance of the airplane and its navigation and flight instruments make possible the airplane
operation in VFR. The landing gear and thrust-to-weight ratio make possible the airplane
operation from fields (airdromes) with both grass and paved runways.
The airplane may have wheels, skis, or floats. Replacement of wheels for skis may be done
easily in a very short time. On customer request, a quickly deployed parachute recovery system
may be installed on the airplane. The system is used for saving the pilot(s) aboard in emergency
in-flight situations.
Basic dimensions of the airplane
Wing Span 31.27 ft (9.53 m)
Length 20.21 ft (6.16 m)
Height 7.78 ft (2.4 m)
Mean Aerodynamic Cord 4.59 ft (1.4 m)
Wing Area 147 ft2 (13.56 m
2)
Wing Loading 7.5 lb/ft2 (36.85 kg/m
2)
14
Three view drawing of SUPERSTOL
15
Power Plant
The SUPERSTOL is equipped with a four-cylinder four-stroke Rotax-912UL or Rotax-912ULS
carburetor combined cooling engine produced by BOMBARDIER-ROTAX Inc. (Austria). Or
other approved engines.
The engine has a flat-four layout, dry sump lubrication system with a separate oil tank of 3 liters
capacity, automatic valve clearance adjustment, two carburetors, mechanical membrane fuel
pump, double electronic ignition system, integrated water pump, electric starter, integrated
gearbox of 2.273 or 2.43 reduction ratio.
All engine systems (fuel, electric, cooling) are assembled in accordance with Rotax-912 engine
operation manual.
Propeller is a three-blade ground-adjustable pitch.
Engine Manufacturer: BOMBARDIER-Rotax-GmbH (Austria)
Engine Model Rotax-912ULS
Engine Type: Flat Four, Four Stroke
Max. Take-off power 100 hp
Time Limit at full power 5 min (5800)
Max. Revolutions (no time
limit) 5500 rpm
Revolutions a idle 1400 rpm
Max. cylinder head
temperature at pick up point 150
0C (300
0F)
Oil Temperature
normal
maximum
minimum
90 – 110 0C (190 – 250
0F)
140 0C (285
0F)
50 0C (120
0F)
Exhaust Gas Temperature
maximum at take-off
maximum
minimum
880 0C (1620
0F)
850 0C (1560
0F)
800 0C (1470
0F)
Oil Pressure
normal
maximum
minimum
2.0 – 5.0 bar (29 – 73 psi) (above 3500 rpm)
0.8 bar (12 psi) (below 3500 rpm)
7 bar (100 psi) (at cold start, allowed for a short
time)
16
Fuel Pressure
normal
maximum
0.15 – 0.4 bar (2.2 – 5.8 psi)
0.4 bar (5.8 psi)
Fuel Automotive unleaded fuel, minimum octane RON
95
Oil Any automotive oil of API classification “SF” or
“SG”
1.3.2 Propeller
Propeller Manufacturer: KeivProp or as specified
Propeller Type Three blade, ground adjustable pitch, pusher
Fuel and Fuel Capacities
The following fuels may be used:
912 ULS
Minimum RON 90
EN 228 Regular
EN 228 Premium
EN 228 Premium Plus
Oil
The engine has a flat-four layout, dry sump lubrication system with a separate oil tank of 3.2
quart (3 l) capacity. Any automotive oil of API classification “SF” or “SG” may be used.
Operating Weights and loading (occupants, baggage, fuel, ballast)
Maximum take-off weight 1320 lbs (500 kg)
Maximum landing weight 1320 lbs (500kg)
Average Empty weight 737 lbs (335 kg)
17
6.5.1.1 Placards and Markings
Required Placards and Markings:
Throttle
Brake
Elevator trim control
Pilot and copilot PTT controls
Parking brake
Engine choke
Fuel shutoff valves
flaps position
Ignition switch
Landing light, strobe light, and navigation lights
Ignition switches
Passenger warning
Minimum 145 lb in front seat
ELT status
Fuel gauges
Tank marked, quantity and grade required
Stainless data plate in left side of tail.
Light-Sport in two inch size at every entry point
Registration numbers in 12 inch size on each side.
6.5.2 Summary of the performance specifications:
Gross Weight 1320 lb.
Top Speed Sea Level 100 mph IAS
Cruise Speed Sea Level 75% power 90 mpg IAS
Full Fuel Range maintaining reserves 500 miles
Climb rate V(x) 62 mph IAS 900 fpm
Climb Rate V(y) 67 mph IAS 1000 fpm
Stall Speed w/o Flaps 37 mph IAS
Stall speed w/ Flaps 32 mph IAS
Usable fuel/ grade 24 gal, minimum 91 RON auto fuel.
18
Maximum HP at rated rpm 100 hp at 5800 rpm
6.5.1 WARNING NOTICE
WARNING
THERE ARE INHERENT RISKS IN THE PARTICIPATION IN
RECREATIONAL AVIATION AIRCRAFT. OPERATORS AND
PASSENGERS OF RECREATIONAL AVIATION AIRCRAFT, BY
PARTICIPATION, ACCEPT THE RISKS INHERENT IN SUCH
PARTICIPATION OF WHICH THE ORDINARY PRUDENT PERSON IS OR
SHOULD BE AWARE. PILOTS AND PASSENGERS HAVE A DUTY TO
EXERCISE GOOD JUDGMENT AND ACT IN A RESPONSIBLE MANNER
WHILE USING THE AIRCRAFT AND TO OBEY ALL ORAL OR WRITTEN
WARNINGS, OR BOTH, PRIOR TO OR DURING USE OF THE AIRCRAFT,
OR BOTH.
THE OWNER AND OPERATOR MUST UNDERSTAND THAT DUE TO
INHERENT RISKS INVOLVED IN FLYING AN LIGHT SPORT AIRCRAFT,
NO WARRANTY IS MADE OR IMPLIED, OF ANY KIND, AGAINST
ACCIDENTS, BODILY INJURY OR DEATH OTHER THAN THOSE WHICH
CANNOT BY LAW BE EXCLUDED.
THE SAFE OPERATION OF THIS AIRCRAFT RESTS WITH YOU, THE
PILOT.
WE BELIEVE THAT IN ORDER TO FLY SAFELY YOU MUST MATURELY
PRACTICE AIRMANSHIP. OPERATIONS OUTSIDE THE RECOMMENDED
FLIGHT ENVELOPE SUCH AS AEROBATIC MANEUVERS OR ERRATIC
PILOT TECHNIQUE MAY ULTIMATELY PRODUCE EQUIPMENT
FAILURE. YOU ARE REFERRED TO THE OPERATING LIMITATIONS IN
SECTION 2 OF THIS MANUAL.
THE AIRCRAFT WILL REQUIRE MAINTENANCE AS OUTLINED IN THE
APPLICABLE MAINTENANCE MANUALS. LIKE ANY AIRCRAFT,
SAFETY DEPENDS ON A COMBINATION OF CAREFUL MAINTENANCE
AND YOUR ABILITY TO FLY INTELLIGENTLY AND CONSERVATIVELY.
19
Definitions:
Definitions used in the Aircraft Operation Instructions such as WARNING, CAUTION, and
NOTE are employed in the following context:
WARNING
OPERATING PROCEDURES, TECHNIQUES, ETC. WHICH IF NOT
FOLLOWED CORRECTLY, MAY RESULT IN PERSONAL INJURY OR
DEATH.
CAUTION
OPERATING PROCEDURES, TECHNIQUES, ETC. WHICH IF NOT
STRICTLY OBSERVED MAY RESULT IN DAMAGE TO THE AIRCRAFT
OF ITS INSTALLED EQUIPMENT.
6.6 N0. 2 Limitations
Airspeed indicator speed range markings: (IAS)
Stall clean V(s) 37 mph IAS
Stall flaps V(so) 32 mph IAS
Flap extend speed V(fe) 75 mph IAS
Maneuvering speed V(a) 75 mph IAS
Never exceed speed V(ne) 130 mph IAS
Stall Speeds at Maximum Takeoff Weight (VS and VSO)
NOTE: In level flight and during turn stall approach warning is provided by the
aerodynamic characteristics of the aircraft - shaking of aircraft structure and control
yoke.
NOTE: OPERATING PROCEDURES, TECHNIQUES, ETC., WHICH ARE
CONSIDERED ESSENTIAL TO HIGHLIGHT.
20
The stall speed with flaps set to second position at maximum take-off weight and
engine at idle is equal to 34 mph IAS, with flaps in 1st position – 35 mph, with
retracted flaps – 37 mph. Flaps Extended Speed Range (VSO to VFE)The positive
flap operating range is 34 – 75 mph. VFE Max. flap extended speed 75 mph. Do not
exceed this speed with full flap deflection.
Maximum Maneuvering Speed (VA) = 75 mph IAS
VA Max. maneuvering speed. Do not make full or abrupt control movement above
this speed. Under certain conditions the aircraft may be overstressed by full control
movement.
Never Exceed Speed (VNE)= 130 IAS
Crosswind and Wind Limitations
Wind limitations are as follows:
- head winds up to 22 mph (10 meters per second);
- crosswinds up to 9 mph (4 meters per second);
WARNING!
It is highly recommended to choose upwind direction (into the wind), for take-off
and landing with the least cross wind. It will significantly shorten take-off and
landing distances and increase degree of safety.
6.6.6 Service Ceiling
The service ceiling is 13,000 ft. (10,000 for light sport)
6.6.7 Load Factors
Limit load factors for the aircraft at gross weight of 1320 lbs are as follows:
Maximum positive limit load factor +4
Maximum negative limit load factor -2
6.6.8 Approved Maneuvers
All aerobatic maneuvers including intentional spins are PROHIBITED.
Flying in conditions where icing is possible is PROHIBITED
21
Flying in the vicinity of thunderstorms is PROHIBITED
6.6.9 Usable Fuel Capacity
24 U.S. Gallons
The Following Fuels may be used:
912ULS
Min RON 90
EN 228 Regular
EN 228 Premium
EN 228 Premium Plus
6.6.10 Maximum engine power output at a stated RPM
Engine Manufacturer: BOMBARDIER-Rotax-GmbH (Austria)
Engine Model Rotax-912ULS
Engine Type: Flat Four, Four Stroke
Max. Take-off power 100 hp
Time Limit at full power 5 min (5800)
Max. Revolutions (no time
limit) 5500 rpm
Revolutions at idle 1400 rpm
6.6.11 Applicable environmental limitations
The aircraft is not designed for use in IFR, Night VFR, Known Ice, rain (above
drizzle) or snow.
6.6.12 Applicable VFR night or IFR use limitations:
The SUPERSTOL is not current rated for either night VFR or IFR flight. Please
see future developments.
22
6.7. No. 3 Emergency Procedures
6.7.1 General Information
Section 3 contains recommendations to the pilot for extreme situations during
flight. However, these situations caused by airframe or engine malfunction are
extremely rare provided that pre-flight inspections and checks are made regularly.
Adequate training and preparations are needed as well as continued flight training
and review to handle any and all situations that may arise.
6.7.2. Typical best airspeed is best glide speed of 70 mph IAS, except under
special conditions which only the pilot can adapt for.
6.7.3 Emergency Checklists
6.7.3.1 Fire
In Case of fire on board, the pilot(s) must act as follows:
Shut off the fuel taps located up to the left and behind the left Seat as well as
located up to the right and behind the right Seat
Switch the ignition OFF
Establish the airplane into a steady descent Make an emergency landing or
deploy the recovery system.
6.7.3.2 Engine Failure
In case of engine failure during take-off roll switch off the engine ignition
system and discontinue the take-off.
If the airplane is at an altitude of up to 150 feet, switch the engine off and
land right away.
If the engine failed during climb, set the airplane into a steady descent at a
speed of 56 mph and if the altitude permits, turn the plane toward the airfield,
switch the ignition off and land.
If the engine fails during level flight, set the airplane into a steady descent at
a speed of 56 mph, switch the ignition off estimate wind direction and strength,
choose a place for landing and land (preferably into the wind).
Under favorable flight conditions try to restart the engine (see paragraph
3.3).
If at the moment of engine failure the aircraft is over terrain absolutely
unsuitable for landing (mountains, rough country, ravines) and flight conditions do
23
not permit restarting the engine in the air the pilot at his discretion may find that it
is necessary to use the parachute recovery system (if installed).
To activate the Parachute Recovery System (if installed):
Switch the ignition OFF
Pull the handle to deploy the recovery system
If while descending on the parachute, the airplane begins to rotate, the
pilot(s) should use the ailerons and rudder to try to stop the rotation.
The pilot(s) should adopt a safe position to avoid possible injuries from
impact in case of rough landing.
The minimum height of system deployment may be estimated using the following
formula:
Hmin=120+Vy Where Hmin – minimum height of system deployment and
Vy – is the vertical speed of the airplane’s descent.
6.7.3.3 Restarting the Engine
To restart the engine in flight:
Set the throttle to idle engine speed position
Set the ignition switches to the ON position
Turn the key to the start position.
6.7.3.4 Landing with the Engine Stopped
This airplane has no particular handling features during the landing with engine
stopped and flaps up or down. Recommended speed at descent is 56 mph. Entry
into flare and flare out at 1.5 feet with landing speed of 38 mph. Maximum lift-to-
drag ratio for the airplane is approximately 12 with flaps up and 8 with flaps down.
The maximum horizontal distance which the airplane may travel while gliding with
engine stopped in still air may be calculated by multiplying the altitude by the lift-
to-drag ratio.
6.7.3.5 Precautionary landing with engine power.
See 6.7.3.4 above and adapt added capability of power to adjust.
6.7.3.7 Loss of oil pressure.
24
Shut down engine and land as in 6.7.3.4.
6.7.3.8 High oil pressure.
See 6.7.3.4 above and adapt added capability of power to adjust.
6.7.3.9 Emergency descent. Engine to idle, full flaps slow to 60 mph
6.7.3.10 Alternator failure.
Shut down all none essential power uses. Fly anticipating full power loss.
6.7.3.11 Overvoltage.
Monitor the status and seek earliest landing at a safe airport. Fly anticipating full
power loss.
In all of the above cases, fly the aircraft first, do not become distracted. Treat as
precautionary landing with power.
6.7.3.12 Inadvertent Spin Recovery.
WARNING: Intentional spins are prohibited
NOTE: In level flight and during a turn, the stall approach warning is provided by
the aerodynamic characteristics of the airplane – shaking of the airplane structure
and control stick.
A possible recovery of the airplane from an UNINTENTIONAL spin, push forward
the rudder pedal opposite the direction of the spin and then push the stick full
forward. When the rotation ceases, put the rudder in the neutral position and after
reaching a speed of 70 mph smoothly level off the airplane without exceeding the
load factor of +4 g and the maximum allowed speed of 130 mph. THIS IS ONLY A
POSSIBLE SOLUTION AND HAS NOT BEEN PROVEN OR
DEMONSTRATED. GOOD AND SAFE FLYING PRACTICES SHOULD NOT
YIELD A SPIN.
6.7.3.13 Inadvertent icing encounter
25
Seek warmer /lower altitudes. Land as soon a practical and safe.
6.7.3.14 Loss of primary instruments
Seek to use alternate means such as wind sound for airspeed. Do not fly near limit
speeds either too fast or too slow. Land as soon a practical and safe.
6.7.3.15 Loss of flight controls
Each control has some idem that may help. For example flaps for pitch, trim for
pitch, doors for rudder and aileron, throttle for pitch and speed, rudder for banking,
etc. Experiment as necessary. Practice is a good idea so you know what works.
6.7.3.16 Pitot Tube Blockage
Signs of such a failure:
In level flight readings of airspeed indicator do not change with speed
changes
During descent airspeed readings decrease and during climb increase.
Pilot actions:
Inform the ATC officer.
Do not use airspeed indicator readings.
In level flight set the engine speed to 4100 – 4300 rpm. The airspeed in this
case will be 68 – 75 mph.
While descending reduce the engine speed to idle and set the sink rate to 13
fps. The airspeed will be approximately 75 mph.
THE ABOVE ACTIONS ARE ONLY ESITMATES YOUR RESULTS
WILL VARY FOR YOUR AIRCRAFT, AS YOU BECOME FAMILIAR WITH
YOU AIRCRAFT YOU SHOULD DISCOVER THIS FOR YOURSELF.
6.7.3.17 Static Tube Blockage
Signs of such a failure:
Readings of vertical speed indicator and altimeter do not change with altitude
changes.
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Airspeed indicator readings are notably unlikely
During descent airspeed readings increase and climb decrease.
Pilot actions:
Do not use readings of airspeed indicator
Check the airspeed by tachometer readings only.
6.7.3.17 Radio Failure
If there is no radio transmission / reception make sure that:
The radio is switched on
The frequency is set correctly
The headset is plugged in to the radio set
Set the VOLUME to maximum
Set the SQUELCH to OFF
Check the radio reception at other frequencies
Follow all FAA procedures
If the radio connection is lost the pilot(s) must discontinue the flight task, pay more
attention to looking for traffic and in any situation continue to make relevant
reports about aircraft position, pilot actions and flight conditions. Land at a reserve
airfield or the airfield of departure according to airfield regulations.
6.7.3.18 Flying in Dangerous Weather Conditions
Flying in dangerous weather conditions refer to flying in conditions when icing is
possible, during a thunderstorm, dust storm and strong turbulence. Pay attention
continuously to flight condition changes. If flight conditions begin to deteriorate,
make a decision in time to change the route or discontinue the flight.
WARNING: FLYING IN CONDITIONS WHERE ICING IS POSSIBLE IS
PROHIBITED
Having gotten into such conditions the pilot(s) must leave the hazardous area
immediately, abandon the flight task, report to ATC and land at the nearest airfield
or suitable place.
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WARNING: FLYING IN THE VICINITY OF THUNDERSTORMS IS
PROHIBITED
Having noticed the thunderstorm in the area, estimate the available time, the
direction of the thunderstorm approach and land at the nearest airfield or a suitable
place. Tie the airplane down. The control surfaces must be secured with clamps or
stops and the doors must be locked reliably.
Strong turbulence may be dangerous. Avoid it in flight making the decision in time
to change the route or discontinue the flight. Having gotten into strong turbulence
at low altitude, climb immediately to a higher altitude flying away from the source
of the turbulence. During intensive turbulence, the airspeed must be at least 62
mph and the altitude must be at least 330 feet. Turns must be performed with bank
angle not more than 300. In a case when flying into turbulence cannot be avoided,
choose an open field and land without exceeding the limit values of speed and
bank angle.
WARNING: DO NOT FLY INTO A CLOUD
Having flown into a cloud, fly out of it descending and checking the airspeed and
bank angle. When the horizon line is obscured by cloud the bank angle may be
checked by vertical orientation of the compass reel.
6.7.3.20 Wind Sheer Effect on the Airplane
Wind sheer is the difference in wind direction and velocity at low altitudes in which
the airplane may be suddenly shifted from the desired flight path. The wind sheer
is most dangerous when the airplane is at the final stage of flight, i.e. during final
approach. Due to increase of tailwind component and decrease of headwind
component near the ground the airspeed decreases, lift drops and the sink rate
increases. Such a situation may occur suddenly so the pilot should know when and
where the phenomenon may be expected and must be ready to act accordingly to
ensure safe flight and landing.
Most often wind sheer is connected with:
Passing fronts
Forming of thunderstorm clouds
Significant inversion at altitude of 150 – 650 feet.
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When expecting wind sheer, the approach must be performed at a speed of 62 mph
minimum. The pilot must be ready to increase engine speed to full power and
perform a go-around.
6.7.3.21 Wake Turbulence
Getting into the wake turbulence of another, especially larger, airplane may be
dangerous. Wake turbulence is created by propeller slipstream and wingtip and
fuselage generated vortices. Getting into wake turbulence may cause complete loss
of aircraft control. Most dangerous is the wake turbulence during take-off, initial
climb, final approach and landing.
WARNING: AVOID GETTING INTO WAKE TURBULENCE
6.7.3.22 Landing off of an Airfield
In cases where out landing is imminent, the pilot should do the following:
Select a suitable place for landing
Pilot training and decision making is needed in order to prepare for such an
instance
Determine the wind direction looking at land features (smoke, trees,
shadows, etc.)
Make a suitable landing
When landing where there is dense and high vegetation (crops, bushes, etc.), select
the top of it as ground level for leveling off.
Emergency landing on water (ditching) or forest must be done by flaring with fully
extended flaps. When landing on forest select the densest part of it selecting tree
tops as ground level for flaring. When ditching, unfasten seatbelts and unlatch the
doors in advance in order to leave the aircraft promptly. Use the water surface as
ground level for flaring. The above are only suggestions and have not been tested
for certified. Quality training and currency are needed to make such a decision.
The full flaps suggested landing is for the slowest speed. One may find the
circumstance requires a different configuration.
6.8 No. 4 Normal Procedures
6.8.1 Pre-Flight Check
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Pre-flight inspection of the airplane should ensure that:
The fabric of the wing and tail and windshield glass are intact
That all control system stops and pitot tube covers are removed
There is no water blockage in the full and static air pressure lines
The fuel tank caps are closed tight
There are no fuel or oil leaks
Fuel is of the correct Octane for engine type.
Fuel quantity has been checked visually as well as via gauges, and is
sufficient for the concerned flight, and meets all applicable rules and
regulations.
Fuel is sampled from drainage point
All belts and hoses are secure and in good condition.
Engine cover is locked and secured
All tie down ropes are removed for flight and or taxi
All lights required for flight are operable
All logs and papers for the aircraft are checked
WARNING: IT IS STRICTLY FORBIDDEN TO FLY THE AIRPLANE THAT
IS EVEN PARTIALLY COVERED WITH FROST, SNOW, OR ICE.
The pilot should inspect the interior of the cockpit and make sure that its equipment
is intact and there are no foreign objects. The pilot should fit the harness belts and
remove the securing pin from the recovery system deployment handle (if installed).
Sitting in the pilot seat the pilot should do the following:
Check the control stick or yoke for free and easy movement
Set the trim tab lever to the neutral position visually check as well as
lever position
Compare the readings of air pressure on the barometric scale of the
altimeter with the true value for the airfield (the big arrow of the
altimeter should be pointed to zero before that) – error must not
exceed 0.03 psi
Check weather the engine control system is in good condition
Check the amount of fuel in the tank
Check the readings of the magnetic compass
Make sure the engine ignition switch is set to OFF position.
6.8.2 Engine Starting
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Before starting the engine:
Set Parking Brake
Master Switch ON
Navigation lights ON
Set the throttle in the idle position
Pump the fuel to the engine by the hand pump or throttle and or
electric pump
Set the choke lever as needed
Turn both Magneto ON
Engage the Starter to start the engine
Look for oil pressure (minimum based on Engine type refer to engine
manual)
Use choke as need from this point on. Refer to engine manual
Aircraft electronics as needed ON
The engine Operator’s Manual should be followed for the correct engine starting
procedure.
Engine starting
For engine start procedures refer to the engine Operator’s Manual.
6.8.3 Taxiing
Before taxiing, make sure the taxi way is clear.
Flight controls are free
Flaps are UP
Engine instruments are indicating and correct
Set Trim to Neutral Position Check Visual, note position of Trim lever
Aircraft is TRIM SENSITIVE
Release parking brake.
Taxiing:
The required speed for taxiing should be chosen depending on the taxiway
condition, visibility and presence of obstacles. Direction of taxiing is controlled
with the rudder pedals. To check the brakes, set the engine speed to idle, pedals in
the neutral position and step on the brake pedals.
WARNING: DO NOT APPLY THE BRAKES ABRUPLY AT HIGH SPEED
BECAUSE THE AIRPLANE MAY GO NOSE OVER.
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When taxiing with cross-winds, the airplane tends to turn into the wind. If the wind
is stronger than 22 mph the airplane, during taxiing, should be followed by
someone from the windward side near the wing tip.
6.8.4 Normal Takeoff
STOL Takeoff
The shortest ground run take-off under standard conditions at 1320 lbs. or less can
usually be accomplished with full-flaps, I.e., 40°. (This will not, however, provide
the best angle of climb if barrier clearance is the objective.) Use of the 30° or less,
depending on load and pressure altitude, is recommended.
Align aircraft along intended take-off track. Apply full power in a steady manner.
Do not “jam” the throttle forward. Release brake as power is applied. Holding
brakes on while full power is being applied is not necessary, or desirable. Keep
aircraft straight on track using rudder. Try to avoid application of the foot brakes
unless required to maintain directional control.
After the air speed reaches approximately 15 or 20 MPH during take off roll, apply
forward pressure on the control stick just enough to lift the tail about 12 or 18
inches off the ground, i.e., or about half of the conventional full tail up position.
At approximately 35 MPH, apply back pressure on the stick in a positive manner
but not so fast that the tail wheel strikes the ground. If the tail wheel is allowed to
strike the ground, the ground run distance will be longer.
When aircraft breaks ground, allow it to remain just above the ground for
approximately 2 or 3 seconds, so that the airspeed will build up to over 50 MPH
before the airplane starts full climb-out. Establish a climb-out speed of 60 to 65
MPH as soon as practical.
Experience gained in this type of take-off will enable the pilot to determine the
amount of stick movement and/or rapidity of action necessary to get the aircraft
airborne with a minimum of ground run. The type of minimum ground run take-off
is most useful when the ground is rough, bumpy, muddy or when very low
obstacles, such as hedges, fences, ditches, etc, are present.
Normal Take Off
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A relatively tail-high technique can also be used to allow airspeed to build up for
better directional control before breaking ground. The tail-high take-off is helpful
when the take-off area is very narrow and when visibility over the nose may be
essential (safer) than breaking ground sooner in the tail-low attitude. In turbulent,
gusty air or very rough ground, this technique can also eliminate the difficulties that
arise from becoming airborne prematurely from the three-point position and then
striking ground again with a side wise drift.
Crosswind Take offs
Takeoffs are allowed with the crosswind component not stronger than 15 mph.
Take-off with a crosswind must be done without extending the flaps. The airplane
tends to turn into the wind during take-off so the stick should be moved to the wind
side from the very beginning of the take-off roll. This is necessary for maintaining
equal loads on the main landing gear wheel and preventing the banking and turning
of the airplane into the wind.
As the speed of the airplane and aileron efficiency increases, gradually return the
stick to the neutral position to prevent the airplane from leaving the ground from
one wheel.
If the airplane starts to turn during take-off, it is necessary to stop this tendency by
deflecting the rudder (pressing the pedal) to the side opposite the turn.
After lift-off, in order to prevent drifting it is necessary to hold the stick shifted
against the drift (i.e. maintain bank to compensate for the drift) and the airplane’s
tendency to turn should be compensated by pushing the pedal opposite to the bank.
When taking off with a crosswind the lift-off speed should be 3 – 7 mph higher
than normal.
6.8.5 Best Angle of Climb (VX)
Recommended speed at climb is 65 mph IAS.
6.8.6 Best Rate of Climb Speed (VY)
Recommended speed at climb is 70 mph IAS.
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6.8.7 Cruise
During level flight the airplane is stable and easily controllable throughout the
entire speed range and any operational center of gravity position. Level flight
speed range is from 65 to105 mph. The control stick force in pitch may be
removed with elevator trim tab deflection.
Steep turns are allowed at an altitude of not less than 165 feet with a bank angle of
not more than 60 degrees. Periodically check the amount of fuel remaining in the
fuel tank. In turbulence, the airspeed should be less than 75 mph, altitude not less
than 330 feet and turns should be made with a bank angle not more than 30 degrees.
6.8.8 Approach
Having obtained the clearing for final and airfield condition information adjust the
altimeter according to the airfield pressure.
At an altitude of not less than 160 feet AGL set the flaps in the landing position
taking into account the strength of the wind. It is NOT RECOMMENDED to
extend the flaps with a headwind of more that 18 mph.
After entering into final, set the throttle to idle position and descend at a speed of
65 mph. Watch the altitude, bank and drift.
When below the glide slope, DO NOT RETRACT the flaps as this will cause some
loss of altitude. This should be corrected by increasing engine power.
6.8.9 Normal Landing
Enter the flare at 15 – 20 feet and flare out at approximately 1.5 feet. Stick
movement should be energetic but smooth and continuous until touch-down. Use
the classic three-point landing technique. During the landing watch the ground 50
– 65 feet ahead and 10 – 15 degrees to the left from the longitudinal axis of the
airplane.
During the flare attention should be shared between the following:
Height and vertical speed
Drift and bank angle
Direction of flight.
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Maintain direction during landing run with the rudder.
Use brakes in the second half of the landing run. Do not apply brakes abruptly as
soon as the airplane touches the ground because it may cause the airplane to nose
over.
Retract the flaps at the end of the landing run.
In the case of landing with the flaps retracted, the glide slope is more shallow and
landing speed and distances are somewhat greater.
Crosswind Landings
The landing may be allowed if the crosswind component is not higher than 15 mph.
Do not use flaps during crosswind landings.
As a crosswind landing is more difficult it is RECOMMENDED to choose in-wind
direction for landing.
Lateral wind component
Causes drift to the airplane in the air or
Turn into the wind on the ground.
During the approach apply a little bank opposite to the wind direction to
compensate for the drift and use the rudder to maintain the direction. When
entering into the flare, start to decrease the bank slowly so that when the airplane
touches the ground the wing levels.
If just before touch-down there is a drift, turn the airplane with rudder pedals
towards the drift to lessen the side load on the landing gear.
Go Around
A go around procedure is possible from any altitude with flaps either up or down.
To do that apply full throttle, climb at a speed of 65-70 mph and at an altitude of at
least 165 feet retract the flaps leaving the engine at full throttle. Repeat circuit and
approach patterns.
After Landing
After landing clear the runway and taxi in for parking.
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Before stopping the engine, set the minimum stable engine speed with the throttle
and let the engine cool down for 1 to 2 minutes. Set the engine speed to idle and
ignition switches to the off position and turn the ignition key to its initial position.
Post Flight Inspection
After flight, visually check:
The fuel tank and engine for leaks of fuel or oil
Weld seams of Power plant
Condition of the propeller blades
Condition and inflation of the tires
Landing gear spring for deformations and cracks
The condition of the fabric covering the wing and tail
After a flight in humid conditions or winter check the transparent
tubes to barometric instruments for water or ice blockage
Refuel if necessary
6.8.10 Short Field Takeoff and Landing Procedures
If it is necessary to achieve a short take-off run and distance, pilot should extend
the flaps for take-off. When choosing the flaps setting it is necessary to take into
account the strength of the headwind. With a headwind of 25 mph and more,
extending of flaps is NOT RECOMMENDED.
There are no peculiar difficult features in airplane behavior with flaps extended.
At an altitude of about 300 ft retract the flaps, maintaining the takeoff power of the
engine.
6.8.11 Soft field takeoff and landing procedures
If it is necessary to achieve a shortest take-off run on a soft field, the pilot should
extend the flaps for take-off. When choosing the flaps setting it is necessary to take
into account the strength of the headwind. With a headwind of 25 mph and more
extending of flaps is NOT RECOMMENDED.
Take-off with full back stick and as the craft leaves the ground, release some back
pressure and allow the aircraft to accelerate to V(x) = 62 mph.
There are no peculiar features in airplane behavior with flaps extended.
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At an altitude of about 300 ft retract the flaps, maintaining the takeoff power of the
engine.
6.8.12 Balked Landing Procedures
Go-around: Go-around procedure is possible from any altitude with flaps either up or down. To
do that apply full throttle, climb at a speed of 65 mph, and at an altitude at least 300
ft retract flaps leaving the engine at full throttle, repeat circuit and approach
patterns.
6.8.13 Information on Stalls, Spins, and any other useful Information
Stall speed
The stall speed at maximum take-off weight, flaps set into 3rd position and engine
at idle is equal to 32 mph, with retracted flaps it is equal to 37 mph. Stall speed
during turn with flaps retracted and bank angle of 60 degrees is equal to 74 mph,
with bank angle of 30 degrees - 55 mph.
Spin recovery
WARNING: Intentional spins in the airplane are prohibited.
NOTE: In level flight and during turn stall approach warning is provided by the
aerodynamic characteristics of the airplane - shaking of airplane structure and
control stick.
To recover the airplane from the spin (unintentional stall) push forward the rudder
pedal opposite to the direction of spin and then push the stick forward. When the
rotation ceases put the rudder in neutral position and after reaching speed of 55
MPH smoothly level off the airplane.
6.9 No.5 Performance
SECTION 5
PERFORMANCE
GENERAL
All of the required performance information applicable to this aircraft is provided by this section.
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TAKE OFF ROLL
From a hard surface, full power at brake release, flaps up. 400 feet.
TAKE OFF ROLL + CLIMB CLEAR 50 FT. OBSTICLE AT 60 KCAS
From a hard surface, full power at brake release, flaps up. 550 Feet
LANDING ROLL – 250 Feet
LANDING DISTANCE
Landing distance from 50 ft. height, flaps down, throttle idle, approach speed = 60 KCAS. 450
feet
RATE OF CLIMB 1320 lbs, flaps up and full throttle at Vy = 70 KCAS, 1000 fpm
CRUISE SPEEDS & RPM
Cruise speeds and RPM in standard atmosphere and 75% power (above 7,000ft. power is less).
At sea level Cruise power of 4800 rpm at 81 mph IAS.
Note: Reducing the power will reduce the speed and fuel consumption and slightly increase the
range.
BEST ANGLE OF CLIMB
V(x) = 65 mph IAS at 950 fpm
CROSSWIND
The demonstrated takeoff and landing crosswind component is 10 mph.
SERVICE CEILING
With a rate of climb of 100 fpm in standard atmosphere: 13,000 ft
AIRSPEED CALIBRATION MPH – FLAPS UP
IAS = 1.00 * CAS
AIRSPEED CALIBRATION MPH – FLAPS DOWN
IAS = 1.00 * CAS
Above calibrations is specific to this aircraft.
NOTE
CAS – Calibrated airspeed means the indicated speed of an aircraft, corrected for position and
instrument error. Calibrated airspeed is equal to airspeed that would be shown on a perfect ASI in
standard atmosphere. Calibrated airspeed expressed in “mph”.
IAS – Indicated airspeed is the speed of an aircraft as shown on the airspeed indicator. Indicated
airspeed expressed in “mph”.
38
STALL SPEEDS AT MAX TAKEOFF WEIGHT
Flaps up: 37 mph IAS
Flaps down: 32 mph IAS
6.9.1 Takeoff Distances
Take-off distance is the sum of the take-off run and the distance flown from lift-off
to an altitude of 50 feet. The take-off distance depends on the airfield elevation, air
temperature, direction and strength of the wind. The available take-off distance in
any conditions must be not less than 800 feet.
6.9.2 Landing Distances
The landing distance is the sum of distance flown from an altitude of 50 feet to
touch-down and landing run. It depends on airfield elevation, air temperature, and
direction and strength of the wind. Required landing distance in any conditions
does not exceed 800 feet.
In case of landing with flaps retracted the glide path is shallower, landing speed and
landing distance slightly increase.
6.9.3 Rate of Climb
The airplane’s rate of climb depends on ambient air temperature and take-off
weight. Climb should be performed at an optimum speed of 62 mph IAS.
6.9.4 Cruise Speed
The cruising speed in level flight is 90 mph IAS
6.9.5 RPM
The engine speed at cruise is 5250 rpm. Maximum flight endurance at economical
engine speed at sea level, standard atmosphere and full fuel tanks (24 gallon) is 4.3
hours. (5.5 gallons/hour)
6.10 No. 6 Weight and Balance and Equipment List
In order to achieve the performance and flying characteristics which are
designed into the airplane, it must be flown with the weight and center of gravity
(C.G.) position within the approved operating range (envelope). Although the
39
airplane offers flexibility of loading, the pilot must ensure that the airplane is
loaded within the envelope before attempting to take off.
Miss-loading carries consequences for any aircraft. An overloaded airplane
will not take off, climb or cruise properly. The heavier the airplane is loaded, the
less climb performance it will have.
C.G. is a determining factor in flight characteristics. If the C.G. Is too far
forward in any airplane, it will be difficult to rotate for takeoff or landing and the
nose gear overstressed at landings. If the C.G. is aft of the approved limit, the
airplane may rotate prematurely on takeoff or tend to pitch up or down; the aircraft
will be unstoppable in pitch. This can lead to inadvertent stalls and even spins; stall
and spin recovery may be impossible in an improperly loaded airplane.
A properly loaded airplane, however, will perform as intended. Before the
airplane is delivered, it is weighed, and the corresponding empty weight and C.G.
location is computed (the empty weight consists of the standard empty weight of
the airplane plus the optional equipment). Using the empty weight and C.G.
location, pilots can easily determine the weight and C.G. position for the loaded
airplane by computing the total weight and moment and then determining whether
they are within the approved envelope.
The empty weight and C.G. location are recorded in the Weight and Balance
Record Form. The current values should always be used. Whenever new equipment
is added or any modification work is done, a new empty weight and C.G. position
should be determined and recorded. The owner must make sure that this is done.
To determine a new empty weight C.G., the airplane must first be weighed
and then the new C.G. position must be calculated.
To determine the C.G. for the loaded airplane, loaded weight and balance
calculations must be performed before flight.
This section specifies the values of payloads approved for safe operation of the
aircraft, as well as the weighing results and method of determining the permissible
payload.
6.10.1-3 Center of Gravity (CG) Range and Determination
Weight of the empty aircraft is equal to 737
Airplane Weight and Balance Just Aircraft Date: 12/13/13
Model: SuperStol (version of Highlander) Registration:
Gross Weight 1320 Serial #:
CG Range:24.5% to 37.3% Mean Chord 12.5 – 19.0 Level Flight:is cockpit rails level. Datum is: Leading edge slats retracted
Empty Weight & CG Weight Arm Moment
Tail Wheel 88 164.25 14,454
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Left main wheel 329.4 -5.25 -1,729
Right main wheel 319.8 -5.25 -1,679
Ballast 0 0 0
Front Seat 0 17.5 0.0
Wing Fuel Tanks 0 18.5 0.0
Aircraft empty weight 737.2 11045.7
Empty CG 14.98
Most Aft Weight & CG Weight Arm Moment
Aircraft Empty 737.2 11,045.7
Left Seat 240 17.5 4,200
Right Seat 180.8 17.5 3,164
Baggage 0 40 0
Wing Fuel Tanks 162 18.5 2,997.0
Weight 1320 21,407
CG 16.22
Most Forward Weight & CG Weight Arm Moment
Aircraft Empty 737.2 11,045.7
Left Seat 120 17.5 2,100
Right Seat 0 17.5 0
Baggage 0 40 0
Wing Fuel Tanks 6 18.5 111.0
Weight 863.2 13,257
CG 15.36
Flight Test Weight & CG Weight Arm Moment
Aircraft Empty 737.2 11,045.7
Left Seat 280 17.5 4,900
Right Seat 248.8 17.5 4,354
Baggage 0 18.5 0
Wing Fuel Tanks 54 18.5 999.0
Weight 1320 21,299
CG 16.14
There is no rational condition for which the CG is out of range.
***NOTE: The ACTUAL Aircraft Weight and Balance will vary from the above
sample. Please refer to the Actual Aircraft specific Weight and Balance Data.
6.10.4 Installed Equipment List
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VFR Option: Altimeter, Airspeed indicator, compass, Radio and glass panel
options, fuel gauges (left and right tank), Emergency Locating Transmitter (ELT);
ELT condition Indicator, Transponder option:
Advanced VFR Option: Altimeter, Airspeed indicator, compass, Electronic Flight
Instrument System: EFIS :(Dynon D-180 or GRT Sport EFIS or TrueTrak EFIS or
other similar EFIS), MicroAir 760N Radio, Lynx Radio Powered interface, Lighter,
fuel gauges (left and right tank), Emergency Locating Transmitter (ELT); ELT
condition Indicator, nav and Strobe.
6.11 No. 7 Description of Airplane and Systems
6.11.1 General, The SUPERSTOL is a two seat light airplane for primary training. It is a high wing, strut braced
monoplane of “classic” aerodynamic layout with closed cockpit, non-retractable landing gear, tail
wheel. It is equipped with a Rotax 912ULS tractor engine and a three blade, ground adjustable
pitch propeller.
Performance of the airplane and its navigation and flight instruments make possible the airplane
operation in VFR. The landing gear and thrust-to-weight ratio make possible the airplane
operation from fields (airdromes) with both grass and paved runways.
6.11.2 Airframe.
Welded chrome moly tubing and fabric, tube AL wing stars and pressed AL ribs.
6.11.3 Flight controls.
Standard elevator, rudder and ailerons, as well as flaps.
6.11.4 Instrument panel.
Panel in front of forward pilot.
6.11.5 Flight instruments.
Standard ASI, compass, fuel quantity, ELT status, engine gauges, altimeter and
options.
6.11.6 Engine.
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Rotax 912ULS 100 HP (see engine section)
6.11.7 Propeller.
Keiv Prop or as specified.
6.12 No. 8 – Handling and Servicing:
6.12.1 Introduction
6.12.2 Ground handling
Aircraft Ground Handling and Servicing
Airplane handling, servicing and maintenance
The extended storage of the airplane is possible either in a hangar or in the open air.
In the latter case the airplane should be parked in the special place equipped for
airplane tie-down. When parking the airplane take into consideration the prevailing
wind direction. The airplane should be parked with its nose into the wind.
6.12.3-4 Towing and Tie-down instructions
The parking devices must provide safe airplane tie-down in the strong wind
conditions. The airplane is tied by three points: upper (on the wing) wing strut
fittings and tail wheel spring.
NOTE: Do not pull the ropes too tight. It will overload the wing structure and
cause it deformation.
When keeping the airplane in the open air do the following:
1. Secure the wheels with brake shoes from both sides; put the tail wheel in neutral
position.
2. Fix the elevator, rudder and ailerons in neutral position with screw clamps.
3. Cover the engine, canopy and Pitot tube with protective covers. Particular
attention should be given to protection of the airplane from corrosion. Mainly it
consists of keeping the protective coatings intact.
Good care of fabric covering of the wing and tail is important for maintaining the
airplanes high flight performance and reliability. For keeping the fabric covering in
good condition do the following:
1. Regularly clean the covering of dust, dirt, moisture and snow (in winter).
2. Protect it from scratches.
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3. Avoid the contact of the covering with oil products, solvents, alkali and acids.
WARNING: DO NOT FLY the airplane if its fabric covering has even the slightest
tear. Repair it first.
Canopy is made of acrylic glass. Wipe it with a clean and soft piece of cloth soaked
in soapy water. Oil stains must be removed with cotton wool soaked in kerosene.
Do not use gasoline, solvents and acetone - they cause glass hazing.
6.12.5 Servicing fuel, oil, coolant, and other operating fluids as applicable
See Maintenance Manual and Engine Manual.
6.12.5.1 Approved fuel grades and specifications
In all matters concerning engine maintenance, refer to the engine Operators
Manual.
6.12.5.2 Approved oil grades and specifications
In all matters concerning engine maintenance, refer to the engine Operators
Manual.
6.12.6 Cleaning and Care.
See Rotax manual for engine, for aircraft only use mild detergent and water.
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6.13 No. 9 – Supplements:
6.13.1 Any additional information the manufacturer wishes
to add regarding the airplane.
Required Placards and Markings:
Throttle
Brake
Elevator trim control
Pilot and copilot PTT controls
Parking brake
Engine choke
Fuel shutoff valves
flaps position
Ignition switch
Landing light, strobe light, and navigation lights
Ignition switches
Passenger warning
Minimum 145 lb in front seat
ELT status
Fuel gauges
Tank marked, quantity and grade required
Stainless data plate in left side of tail.
Light-Sport in two inch size at every entry point
Registration numbers in 12 inch size on each side.
Airspeed Indicator Range Markings
Airspeed is indicated in Miles per Hour. The airspeed indicator has colored arcs
that indicate aircraft speed ranges. (IAS)
White Flap Extended V(so)- V(fe) 32 – 75
Speed Range
Green Normal Speed V(s) – V(a) 37 – 75
Range
Yellow Smooth Air V(a) – V(ne) 75 –130
45
Speed Range
Red Never Exceed V(ne) 130
Speed
Operating Limitations on Instrument Panel
This aircraft is NOT approved for Aerobatic flight and INTENTIONAL SPINS
ARE PROHIBITED.
Passenger Warning:
“This aircraft was manufactured in accordance with Light Sport Aircraft
airworthiness standards and does not conform to standard airworthiness
requirements.”
Miscellaneous Placards and Markings Listed in Section 6.5.1.1 and 6.13.1 above.
Pilot Operating Advisories None
6.13.2 Operation of optional equipment or accessories
6.13.3 Airplane flight training supplement (FTS)
Familiarization Flight Procedures
Pilots new to the SUPERSTOL should allow sufficient time with a trained
instructor to become familiar with the aircraft.
Low weight, high drag, means handling is different than a Cessna.
Things to watch for are:
1) Quick deceleration when power is reduced.
2) Engine out on takeoff compounds the problem by combining higher stick
force against the pitch up and quick deceleration. The pilot must know and be
ready for effective stick forward response.
6.13.4 Information the owner can use for:
46
6.13.4.1 Improvements or Corrections
Contact the factory listed on the title page with any requests or information
important to this aircraft.
6.13.4.2 Continued Operational Safety Reporting
Your reporting to the factory of any issues or problems with the aircraft is a very
important part of improving aviation safety. Factory personnel will help you pull
together the correct information necessary to understand and potentially correct
what may be vital issues. Please report quickly if there are any issues with the
aircraft.
6.13.4.3 Change of Address Notice
Reporting any change of ownership or of owners address is also very important so
that information items may be reported to you without delay. When you do an
annual condition inspection on this aircraft you must download the latest
maintenance manual from the official web site www.justaircraft.com . This is your
way to make sure you have the latest information.
6.13.5 Owner/operator responsibility
6.13.5.1 Each owner/operator of a LSA shall be responsible for providing the
manufacturer with current contact information where the manufacturer may send
the owner/operator supplemental notification bulletins
.
6.13.5.2 The owner/operator of a LSA shall be responsible for notifying the
manufacturer of any safety of flight issue or significant service difficulty upon
discovery.
6.13.5.3 The owner/operator of a LSA shall be responsible for complying with all
manufacturer issued notices of corrective action and for complying with all
applicable aviation authority regulations in regard to maintaining the airworthiness
of the LSA.
6.13.5.4 An owner of a LSA shall ensure that any needed corrective action be
completed as specified in a notice, or by the next scheduled annual inspection.
47
6.13.5.5 Should an owner/operator not comply with any mandatory service
requirement, the LSA shall be considered not in compliance with applicable ASTM
standards and may be subject to regulatory action by the presiding aviation
authority.
48
Maintenance Manual
ELSA and Experimental
Handling and Servicing
Introduction
Your aircraft surfaces are covered in a modern heat-shrink fabric and finished as per the fuselage. The tail surfaces are also made of tubular steel construction, and are wire and tubing braced. The surfaces are finished as per the rest of the aircraft. This fabric is tough and durable but care must be taken so as not to puncture it. The windscreen, windows and doors are made from thin transparent polycarbonate sheets.
There is a handle on the rear of the fuselage for ground handling operations. Pushing and pulling by this handle is the recommended way of moving the plane around on the ground.
Your Highlander was designed to be easily towable. Load the plane onto a trailer and secure the wings back locking them into position with transportation jury struts and tie the airframe down to the trailer. Its recommended to support the fuselage at the rear so the tail wheel is not touching. Secure the prop from turning.
Your Highlander has tie down rings incorporated into the wings on each lift strut attach point. Use conventional tie downs on these rings and tie the tail around the tail wheel spring.
Below are the service intervals to be followed for the airframe. (For engine maintenance see the Engine Manual).
It is also permitted for the pilot to make small aileron adjustments at the aileron wire turnbuckles if the aircraft has a natural turn.
Auto gas is permitted and recommended also 100ll.
See engine manual for oil grades and specifications.
Cleaning of your highlander will prolong the service life of the fabric. Use a weak solution of mild detergent in water. Take care not to get water into electrical devices, venturis, pitot heads or static ports. Ensure that the aircraft is then dried thoroughly.
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Record of Maintenance
The Highlander must possess two separate logbooks one for the airframe and one for the engine.
Check A (daily) need not be recorded in the aircraft logbooks unless a defect is found.
Check B (25 hrs / 3 months), and Check C (50hrs / 6 months) and the annual inspection must always be recorded in the appropriate logbooks. A list of all parts replaced must always be given and the invoices or certificates of conformity for these parts must be retained, along with all other aircraft maintenance records, until at least two years after destruction or permanent withdrawal from use of the aircraft.
Preparing the Aircraft for Inspection
Carry out a visual inspection before cleaning the aircraft. Any fretting damage may be visible from powdery deposits around a bolt hole. Leaks or fatigue cracks may sometimes be detected by visible deposits in surface dust or dirt.
The aircraft may then be cleaned if required using a weak solution of mild detergent in water. Take care not to get water into electrical devices, venturis, pitot heads or static ports. Ensure that the aircraft is then dried thoroughly.
If the aircraft has been stored outside, all frost, snow or excessive dew or rain must also be carefully removed.
Inspection must be carried out in a clean environment, with good light.
When to Carry out Maintenance
Check A
Before the first flight of the day.
Before any further flight if the aircraft has been left unattended on an airfield for any period of time.
Check B
At 25hr or 3 month intervals, except when a Check C or annual inspection is carried out instead.
If necessary, Check B interval may be extended by up to 2½hrs or 9 days, but the next check time must still be taken from the due date of the previous inspection.
Check C At 50hr or 6 month intervals, except when a Check C or annual inspection is
carried out instead.
If necessary, Check B interval may be extended by up to 5hrs or 18 days, but the next check time must still be taken from the due date of the previous inspection.
Annual Once per year, timed to co-incide with the annual permit renewal, or at 150
hr intervals (extendable by up to 15 hrs if required).
This may not be extended in time, however if the aircraft is “rested” for some time, the intervals for all other checks may be reset by carrying out an annual inspection.
Note: Airframe and Engine Hours
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Inevitably, airframe and engine hours rarely, if ever, match up. While it is permissible to separate airframe and engine maintenance intervals, this becomes very complicated. It is recommended that whichever has the highest hours (usually the engine) is used as the basis for inspection and maintenance intervals.
Check A - the Daily Inspection (DI)
Paperwork
Check permit to fly is valid
Confirm no B, C or Annual checks are due.
Check that all defects entered into the logbooks are acceptable, or have been rectified.
Aircraft
Checks B, C and Annual
Check B (25hrs /
3 months)
Check C (50 hrs /
6 months)
Annual (Or 150 hrs)
Fuselage
Check all pressure instruments for cracks, leaks and suction
Check all airframe members for cracks, dents, corrosion or deformation
Check all fasteners for security, condition or fretting
Check all rig / derig connections, rings & clips
Check all bracing cables for tension, corrosion or kinks.
Check doors for security and cracks
Check seats for fraying, cracks, security
Check harnesses and belts
Check flying control runs for condition and lubrication
Check operation of all controls
Undercarriage
Check structure for damage or deformation
Check tire pressures (15psi)
Check freedom & play in bearings
Check brakes for wear or damage
Lubricate all joints and bearings
Check steering mechanisms for wear and lubrication.
Toe brakes
Check operation, adjust and lubricate cables.
Propeller
Inspect blades for nicks and splits
Inspect hub for security and condition
Check for vibration on run-up
Inspect leading edge protection (if fitted) for security
Check blade pitch (if ground adjustable)
Fuel System
Inspect tank(s) for cracks, leaks, abrasion
Drain or flush tank
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Check B (25hrs /
3 months)
Check C (50 hrs /
6 months)
Annual (Or 150 hrs)
Inspect all fuel pipes and hose for cracks or perishing. Always replace if unsure.
Inspect system for leaks
Inspect and clean or replace fuel filter. (Check every hour 1
st 40 hours of run-in)
Disconnect hose at pulse pump and confirm fuel flows from tanks.
Check operation of fuel tap.
Electrical
Check electrolyte level of unsealed batteries.
Check security of battery mounting, leaks, connection security.
Check all wiring for condition and security.
Check condition of all switches
Wing
Check all members for cracks, dents, deformation, corrosion or fretting.
Check all cables and thimbles for tension, corrosion, fraying, kinking or fretting.
Check all fasteners for security (nylon-insert self locking nuts are to be replaced with new items if removed for inspection).
Check critical structural fasteners for corrosion and deformation.
Check condition and abrasion of riveting or stitching and gluing of fabric.
Check main spar joint for wear or deformation.
Inspect all rig & derig points for condition and operation.
Ailerons
Check for full and free movement.
Check for any excessive freeplay between ailerons, and between aileron and control column.
Check control deflections.
Inspect all hinges, brackets, push-pull rods, bellcranks, control horns, cables, pulleys
Check control cables and stops have correct tension and friction.
Rudder
Check for full and free movement.
Check connections to tail wheel steering
Check for any excessive freeplay between rudder and pedals.
Check control deflections.
Inspect all hinges, brackets, push-pull rods, bellcranks, control horns, cables, pulleys
Check control cables and stops have correct tension and friction.
Elevator
Check for full and free movement.
Check for any excessive freeplay between elevator and control column.
Pilot Operating Handbook - SUPERSTOL
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Check B (25hrs /
3 months)
Check C (50 hrs /
6 months)
Annual (Or 150 hrs)
Check control deflections match.
Inspect all hinges, brackets, push-pull rods, bellcranks, control horns, cables, pulleys
Check condition and operation of trim tab.
Check all control cables and stops have correct tension and friction.
Doors
Check condition of doors, bracing, hinges, and latches.
Rear Fuselage
Inspect all rear fuselage and tailboom structure through access points.
Supplements
Maintenance and Repair
Fuel System
Check venting system on the fuel cap and determine it is not clogged.
Inspect all fuel lines for cracking, dryrot, and leaks and replace where necessary.
Be sure the curtiss drain valve is clear and not leaking.
Replace the fuel filter with a “non-papered” fuel filter with wire mesh.
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Repairs
General
Repairs should either be carried out as described below, or to a scheme approved by the A&P or I.A.. After making any repairs, you should always obtain a “second inspection” from a qualified pilot or (preferably) A&P or I.A. inspector, who should sign in the logbook that they have inspected the repair and consider it safe. Where this is not possible, at the next permit renewal draw the repair to the attention of your inspector who should oversign your own entry.
Repairs to bolted tubular structure, springs, pulleys, cables, bolts, nuts, etc. Any damage to such parts must not be repaired and the aircraft must not be flown once the damage has been identified. Identical replacement parts must be fitted before any further flight, and their installation inspected and signed-off in the logbook by a A&P or I.A. inspector. The invoice (legally referred to as the Certificate of Conformity) for the parts fitted must be kept with the aircraft logbook. If it is not possible to obtain replacement parts, consult the A&P or I.A. Technical Office for advice.
Repairs to the Engine These should be carried out in accordance with the maintenance manual for the engine fitted.
Repairs to Instruments Light aircraft instruments may be repaired or replaced.
Repairs to Fuel Hose Any fuel hose that found to be cracked or damaged must not be repaired. Replace it with at least automotive quality (preferably aircraft or fire-retardant boat use) re-enforced rubber fuel hose. It is not advised that transparent fuel hose is used, and PVC hose must not be used with fuel under any circumstances. Take care not to over-tighten cable ties used to secure hose, since this can cause a flow restriction.
Damaged Wiring Replace with fireproof or fire resistant wiring of the same or higher current rating, secured in the original manner.
Repairs to Batteries A damaged battery must be replaced and all surrounding structure thoroughly inspected for acid damage.
Repairs to Tires An inner tube puncture may be repaired. If there is damage to the tires that shows the inner canvas, replace the tire in question.
Damage to a Fuel Tank. The fuel tank should be drained and removed from the aircraft. It is unlikely that the tank will be repairable.
Damage to the Fabric Do not attempt to fly if there is damage to the wing or fuselage covering fabric. Repairs should be carried out in accordance with FAA Airworthiness Circular AC43.13-1B chapter 2 section 4, taking care to ensure that the same materials are used as at original build, or - if the aircraft has subsequently been re-covered - the last re-covering.
Damage to The Welded Steel Frame If there is damage, either corrosion or bends to parts of the welded steel frame, do not attempt to straighten any damage, and do not attempt to overpaint or repair corrosion. Any repair must be approved by the A&P or I.A. and is likely to require cutting out the damaged section, welding in a replacement, painting the repair, and then externally sleeving the repair. Guidance notes on such repairs are to be found in FAA Airworthiness Circular AC 43.13-1B chapter 4, section 5.
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Vital Statistics
Weight values for this Superstol are at section 6 and a description of the aircraft limitations are at Section 2. The following describes the basic dimensions of the aircraft:
Superstol Length 19ft Length wings folded 21ft 8in Width wings folded 8ft 6in Height tail wheel version 7ft 5in Span 31ft 3in Mean chord 55in Wing area 147ft
2
Undercarriage track width 98in Fuel capacity 27 gals Tire Pressure (Main wheels, Alaska Bush)
6 psi
Tire Pressure (tail wheel) 15 psi
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ANNEX A
MINOR MODIFICATIONS FITTED TO THIS AIRCRAFT SINCE INITIAL
PERMIT ISSUE
Minor modification approval sheets are to follow this page
Minmod No. Description Sign and date incorporated
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ANNEX B
MAJOR MODIFICATIONS FITTED TO THIS AIRCRAFT SINCE INITIAL
PERMIT ISSUE
MAAN / AAN No.
Issue Description Sign and date incorporated
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ANNEX C
INSTRUCTIONS AND MANUALS FOR OTHER DEVICES FITTED TO THIS
AIRCRAFT
No. Description Issue or date
Approval Mod No, or original equipment
F1 F2 F3 F4 F5 F6 F7 F8 F9 F10 F11 F12 F13 F14 F15 F16 F17
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Service Difficulty and Feedback Reporting Form
This is information that owner must send to Just Aviation to report service difficulties and/or possible safety of flight issues. The data does not have to be in this specific format, however, the data needs to be complete enough for the manufacturer to begin evaluation of the specific issues. Name of reporting party _______________________________________ Date reported _______________ Date of event if any ________________ Make _________________ Model ____________________ S/n_________ Address of reporting party _______________________________________ City, state, zip ______________________________________
_______________________________________ Phone number of reporting party _________________________________ Email of reporting Party _________________________________________ Name of owner if different ______________________________________ Address of owner if different _____________________________________ City, state, zip ______________________________________ _______________________________________ Phone number of owner ________________________________________ Email of owner ____________________________________________ Details of issue: What part _____________________________________ What Happened _______________________________________________ Circumstances (ie. Hard landing, gust front, etc) ____________________ ____________________________________________________________ ____________________________________________________________ ____________________________________________________________ FAA/NTSB contact if any ___________________________________________
____________________________________________________________
Superstol work sheet: contacted _______________________________________ Initial working issue ____________________________________________
Closure if any ______________________________________________ Closing date ________________________ Person __________________ Record number _______
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